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Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection

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Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection. / Chambers, Jonathan; Wilkinson, Paul; Uhlemann, S. et al.
In: Water Resources Research, Vol. 50, No. 7, 07.2014, p. 5886-5905.

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Harvard

Chambers, J, Wilkinson, P, Uhlemann, S, Sorensen, JPR, Roberts, C, Newell, AJ, Ward, WOC, Binley, A, Williams, PJ, Gooddy, DC, Old, G & Bai, L 2014, 'Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection', Water Resources Research, vol. 50, no. 7, pp. 5886-5905. https://doi.org/10.1002/2014WR015643

APA

Chambers, J., Wilkinson, P., Uhlemann, S., Sorensen, J. P. R., Roberts, C., Newell, A. J., Ward, W. O. C., Binley, A., Williams, P. J., Gooddy, D. C., Old, G., & Bai, L. (2014). Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection. Water Resources Research, 50(7), 5886-5905. https://doi.org/10.1002/2014WR015643

Vancouver

Chambers J, Wilkinson P, Uhlemann S, Sorensen JPR, Roberts C, Newell AJ et al. Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection. Water Resources Research. 2014 Jul;50(7):5886-5905. Epub 2014 Jun 30. doi: 10.1002/2014WR015643

Author

Chambers, Jonathan ; Wilkinson, Paul ; Uhlemann, S. et al. / Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection. In: Water Resources Research. 2014 ; Vol. 50, No. 7. pp. 5886-5905.

Bibtex

@article{3e1c17fce1d44d47896988ee79669aa2,
title = "Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection",
abstract = "For groundwater-surface water interactions to be understood in complex wetland settings, the architecture of the underlying deposits requires investigation at a spatial resolution sufficient to characterize significant hydraulic pathways. Discrete intrusive sampling using conventional approaches provides insufficient sample density and can be difficult to deploy on soft ground. Here a noninvasive geophysical imaging approach combining three-dimensional electrical resistivity tomography (ERT) and the novel application ofgradient and isosurface-based edge detectors is considered as a means of illuminating wetland deposit architecture.The performance of three edge detectors were compared and evaluated against ground truth data, using a lowland riparian wetland demonstration site. Isosurface-based methods correlated well with intrusive data and were useful for defining the geometries of key geological interfaces (i.e., peat/gravels and gravels/Chalk). The use of gradient detectors approach was unsuccessful, indicating that the assumption that the steepest resistivity gradient coincides with the associated geological interface can be incorrect. These findingsare relevant to the application of this approach in settings with a broadly layered geology with strata of contrasting resistivities. In addition, ERT revealed substantial structures in the gravels related to the depositional environment (i.e., braided fluvial system) and a complex distribution of low-permeability putty Chalk at the bedrock surface—with implications for preferential flow and variable exchange between river and groundwater systems. These results demonstrate that a combined approach using ERT and edge detectors can provide valuable information to support targeted monitoring and inform hydrological modeling of wetlands.",
author = "Jonathan Chambers and Paul Wilkinson and S. Uhlemann and Sorensen, {J. P. R.} and C. Roberts and Newell, {A. J.} and Ward, {W. O. C.} and Andrew Binley and Williams, {P. J.} and Gooddy, {D. C.} and G. Old and L. Bai",
note = "Copyright 2014. American Geophysical Union Date of Acceptance: 26/06/2014",
year = "2014",
month = jul,
doi = "10.1002/2014WR015643",
language = "English",
volume = "50",
pages = "5886--5905",
journal = "Water Resources Research",
issn = "0043-1397",
publisher = "AMER GEOPHYSICAL UNION",
number = "7",

}

RIS

TY - JOUR

T1 - Derivation of lowland riparian wetland deposit architecture using geophysical image analysis and interface detection

AU - Chambers, Jonathan

AU - Wilkinson, Paul

AU - Uhlemann, S.

AU - Sorensen, J. P. R.

AU - Roberts, C.

AU - Newell, A. J.

AU - Ward, W. O. C.

AU - Binley, Andrew

AU - Williams, P. J.

AU - Gooddy, D. C.

AU - Old, G.

AU - Bai, L.

N1 - Copyright 2014. American Geophysical Union Date of Acceptance: 26/06/2014

PY - 2014/7

Y1 - 2014/7

N2 - For groundwater-surface water interactions to be understood in complex wetland settings, the architecture of the underlying deposits requires investigation at a spatial resolution sufficient to characterize significant hydraulic pathways. Discrete intrusive sampling using conventional approaches provides insufficient sample density and can be difficult to deploy on soft ground. Here a noninvasive geophysical imaging approach combining three-dimensional electrical resistivity tomography (ERT) and the novel application ofgradient and isosurface-based edge detectors is considered as a means of illuminating wetland deposit architecture.The performance of three edge detectors were compared and evaluated against ground truth data, using a lowland riparian wetland demonstration site. Isosurface-based methods correlated well with intrusive data and were useful for defining the geometries of key geological interfaces (i.e., peat/gravels and gravels/Chalk). The use of gradient detectors approach was unsuccessful, indicating that the assumption that the steepest resistivity gradient coincides with the associated geological interface can be incorrect. These findingsare relevant to the application of this approach in settings with a broadly layered geology with strata of contrasting resistivities. In addition, ERT revealed substantial structures in the gravels related to the depositional environment (i.e., braided fluvial system) and a complex distribution of low-permeability putty Chalk at the bedrock surface—with implications for preferential flow and variable exchange between river and groundwater systems. These results demonstrate that a combined approach using ERT and edge detectors can provide valuable information to support targeted monitoring and inform hydrological modeling of wetlands.

AB - For groundwater-surface water interactions to be understood in complex wetland settings, the architecture of the underlying deposits requires investigation at a spatial resolution sufficient to characterize significant hydraulic pathways. Discrete intrusive sampling using conventional approaches provides insufficient sample density and can be difficult to deploy on soft ground. Here a noninvasive geophysical imaging approach combining three-dimensional electrical resistivity tomography (ERT) and the novel application ofgradient and isosurface-based edge detectors is considered as a means of illuminating wetland deposit architecture.The performance of three edge detectors were compared and evaluated against ground truth data, using a lowland riparian wetland demonstration site. Isosurface-based methods correlated well with intrusive data and were useful for defining the geometries of key geological interfaces (i.e., peat/gravels and gravels/Chalk). The use of gradient detectors approach was unsuccessful, indicating that the assumption that the steepest resistivity gradient coincides with the associated geological interface can be incorrect. These findingsare relevant to the application of this approach in settings with a broadly layered geology with strata of contrasting resistivities. In addition, ERT revealed substantial structures in the gravels related to the depositional environment (i.e., braided fluvial system) and a complex distribution of low-permeability putty Chalk at the bedrock surface—with implications for preferential flow and variable exchange between river and groundwater systems. These results demonstrate that a combined approach using ERT and edge detectors can provide valuable information to support targeted monitoring and inform hydrological modeling of wetlands.

U2 - 10.1002/2014WR015643

DO - 10.1002/2014WR015643

M3 - Journal article

VL - 50

SP - 5886

EP - 5905

JO - Water Resources Research

JF - Water Resources Research

SN - 0043-1397

IS - 7

ER -